DE935554C - Selective call switching arrangement, especially for subscriber stations in telephone systems - Google Patents

Description

Selective call switching arrangement, especially for subscriber stations in Telephone systems The invention relates generally to selective signal systems or Call switching arrangements and in particular improvements for selective call systems in Telephone lines, with the aim of creating a more pleasant call.

Furthermore, the invention aims to create a device by which the number of subscriber station types that are in a particular system must be provided in order to meet different operating conditions or a enabling selective response is significantly reduced. In the inventive Facility's individual parts can optionally be used for several different tasks will.

To achieve these properties, the invention is used for reception a call current superimposed on a direct current or a direct voltage (alternating current) one of a capacitor and the coil of a pager in parallel resonance A circle tuned to the ringing frequency is provided, which is in series with a polarizing Resistance, e.g. B. a cold cathode tube, a rectifier od. Like. Such is connected that when the combined DC and AC voltage is applied the mentioned series connection of the resonant circuit responds and actuates the call device.

With this facility z. B. the coordinated circle in each period be triggered once, whereby the oscillation of the resonance frequency is continuously maintained will.

A magnetic armature speaks to the oscillation current with a by a spring pretensioned clapper, which alternates against two Bells strikes, the impulses arriving when the clapper is against the tension of the spring works.

The right choice of switching elements and the spring force can be achieved that both bells alternate with the same force and in. equal time intervals be posted.

. The polarization of the receiving devices allows a Line to connect two differently polarized receiving devices through Polarity reversal of the DC voltage can be called optionally on the transmitter side. If there is a double line, a few different can be found on each of the individual conductors Connect polarized receiving devices with one pole each, while the rest Poles are on earth.

By means of a special contact device it can also be achieved that the resonance capacitor is temporarily connected as a spark release capacitor in parallel to the number pulse contact, namely for dialing digits, so that a special capacitor can be saved represent, described in more detail. FIG. 1 shows a subscriber station circuit in which the invention is applied; FIG. 2 shows four different exemplary embodiments of the new and improved ringing circuit for a quadruple line, namely A, B, C, D; Figure 3 shows a graphical representation of the voltage and current waveforms obtained by the new and improved ringing circuit using device A.

In the present device there is a gas-filled one which is known per se Cold cathode tube in series with a biased call device with parallel connected Capacitor. The coil inductance and the capacitance of the pager's capacitor are dimensioned so that the combination is tuned to 2o Hz. The superimposed Impulse call current is required for selectivity and is used in the central station generated. The power source contains a standard 20 Hz call generator in series with a direct current source, resulting in a current that is known as an alternating current can be viewed whose neutral axis is from the center line of the shaft around the The amount of direct current voltage is shifted. Because the gas-filled cold cathode tube is a rectifier, the correct combination of ac call voltage gets and the DC voltage produces an interrupted current connection through the tube. The first ringing impulse through the tube causes the resonance circuit to start oscillating. The following Pulses in the resonance frequency, e.g. B. 20 Hz occur; replace the loss of performance in the coordinated storage circuit and maintain the vibrations. The call facility can be of the type described in US Pat. No. 2,082,095 is.

The current in the calling coils reverses its direction twice in each period around, and accordingly the anchors and the associated clapper become the stop of every bell operated once in the period. The impulse let through the tube becomes, seen in time, occur during the half-wave in which the clapper against the force of the preloaded spring is working. The magnetomotive force of the call coils is thereby amplified during this half-wave. During the other half-wave, if the tube is non-conductive and no pulse is applied, it assists The tension of the spring is the magnetomotive force created by the natural oscillatory current caused, and presses the clapper to stop the other bell. the both bells are therefore struck and give with equal force thereby the same tone vibrations.

It should be noted that a gas-filled cold cathode tube as shown in FIG. The present device is used, is not necessary to the desired to receive selective call actuation. There are other arrangements which are nonlinear have asymmetrical conductivity. Different types of rectifiers can be used become, such as B. a dry rectifier made of selenium, copper oxide, copper sulfite, Alumina and many others. The invention is not intended to be limited to any of these be.

It will now be a detailed description of the shown in the drawing Embodiments of the invention are given.

The subscriber station in Fig. I with the exception of the new and improved Ringing corresponds exactly to the subscriber station in the USA patent specification 2 cig. 259 is shown. The ringing circuit A in Fig. 2 contains the subscriber station in Fig. i and should therefore be considered first. With this facility the zoo pager is only activated when a negative superimposed ringing voltage from the line - L is applied to earth. In the present invention the DC voltage approximately 50 volts and the 20 Hz AC call voltage approximately 9o volts The tube used here has three electrodes: an ignition electrode, a main anode and a cathode. The tube is non-conductive as long as it is not The voltage applied between the ignition electrode and the cathode reaches approximately 70 volts. Once the tube is through the lowest voltage required between the ignition electrode and the cathode is ionized, the main flow of electrons goes from the cathode to Main anode over. Assuming a positive voltage on the main anode and a negative voltage at the cathode, the tube becomes conductive when the voltage 75 volts or higher.

The voltage drop across the electrodes is practically independent of the current flow. For a better understanding of the operation of this circuit, a complete period of the pager will be considered with reference to FIG. It should be remembered that in order to operate the zoo pager, the go-volt ringing voltage is shifted from the zero line (earth potential) by a negative 5o-volt DC voltage. Since the voltage from the main station battery via the line - L to earth is only 50 volts negative at the beginning of a period, the tube TA is non-conductive. The negative 50 volts may be applied to cathode 2o4 from line -L through pager Zoo. The ignition electrode 2o6 is connected to earth potential via the resistor 2o5. Since the AC call voltage of the source via the line -L becomes increasingly negative, as can be seen from FIG. 3, the total voltage from the cathode 204 to the ignition electrode 2o6 will of course also become more negative. If the value of the superimposed ringing voltage is -2o volts, the total voltage between the ignition electrode 2o6 and the cathode is 204 -7o volts (30i in FIG. 3), and the tube TA becomes conductive. As previously stated, the 70 volts are sufficient to ionize the gas and allow current to be conducted from the cathode 204 to the main anode 203. Thus, when tube TA is ionized, a circuit for the coils of pager Zoo is completed through the following path: pager 2o0, cathode 204, tube TA, main anode 203, ground, main station power source, line - L to pager 200. Begins at the same time the capacitor toi be charged in parallel with the coils of the zoo pager and in series with the normally closed contact 2o2 of the hook switch. As the alternating voltage becomes increasingly negative, the capacitor toi continues to charge. The current flow through the coils of the call device 200, which is shifted from the voltage by a little less than 9o ° in a known manner, reaches the value of the magnetic voltage which is necessary so that the magnetic voltage overcomes the bias of the spring and causes the Klöppel does the first stop. The alternating voltage then reaches the negative peak value (3o2) and begins to rise again. At point 302 in the voltage period, all of the energy is stored in the capacitor. The capacitor gor then discharges through the coils of the zoo pager. When the AC ringing voltage has risen to about -2o volts, the total voltage becoming -7o volts (3o3), the tube TA ceases to be conductive. It does not conduct during the rest of the half-wave or in the corresponding positive half-wave, since the total voltage difference between cathode 2o4 and main anode 203 or ignition electrode 2o6 is always less than the required minimum. The capacitor will of course be completely discharged via the pager Zoo, whereby the stored energy is transferred from the capacitor toi to the coils of the pager 200. At point 3o4, practically all of the stored energy is in the coils of the zoo pager. The magnetic energy in the coils of the pager Zoo begins to charge the capacitor toi to an opposite polarity as previously described. (see. Fig. 3). The current flowing through the coils of the zoo pager has, up to this point, e.g. As can be seen next to 3o5, the same direction as seen from the waveform in Fig. 3 by the points 307-308. The capacitor toi is then fully charged by the magnetic energy of the coils (point 305 in the voltage period) and, since the tube TA is non-conductive at this moment, the capacitor toi discharges through the coils of the pager Zoo in the opposite direction. The shifted current from point 308 to 309 in the current period now has a direction such that it moves the armature and the associated clapper and thereby supports the preload spring in returning the clapper and striking the second bell. The capacitor gor is charged again by the magnetic energy of the coils of the pager 200 in the opposite direction (point 3o6 in the voltage period) and causes the initiation of a new period. However, if two elements, such as B. the coils of the pager 200 and the capacitor gor, are precisely tuned to 2o Hz, the next pulse appears in the following paging period and amplifies the voltage wave, provided that a power source is provided for the power destroyed in the resistor of the circuit. This mode of operation occurs naturally in every period and is well known as the flywheel effect. Thus it can be seen that the oscillation causes each bell to be of the same strength - substantially different from the previous one-way actuation in which the spring preload is the main force required to strike one of the bells. was used - is posted. It can also be seen that the attacks have exactly the same time intervals.

The operation of circuit B in Fig. 2 is exactly the same, as described for A, except that the negative was superimposed Ringing voltage is transmitted to line -! - L instead of line - L.

From the circuit arrangement C in FIG. 2 it can be seen that the cathode 404 is connected to ground potential. Therefore, in order to make the tube TC conductive, an alternating ringing voltage, which is superimposed on a positive direct voltage, is required at the ignition electrode 406. The positive half-wave then increases the voltage at the ignition electrode 4o6 up to the ionization point. Therefore, in this device, the tuned circuit with the coils of the pager 400 and the capacitor 40i receives pulses from the tube TC during the positive half-wave in order to maintain the oscillation. Recall that when switching arrangements A and B were operated, pulses were received during the negative part of the period.

The operation of the switching arrangement D in Fig. 2 is of course that same as that previously described for C, except that the positive one superimposed Ringing voltage is applied to line -i- L instead of line -L.

The circles A, B, C and D are also set up so that they make the call over the lines or the call over earth in a very simple manner. The circuit A can be modified in the former case by removing the conductor 2o7 from the line -L and connecting it to the line -I- L.

An earth call via the -L line can be achieved by distance of the conductor 2o7 and earthing of the same.

Accordingly, a grounded call can be established over the line -i- L are made by removing the two conductors 2o8 and 2o7 connecting the one on line -f- L and the other to a grounded power source. In the same way circles B, C and D can be changed. The tubes are in this case not used and can be omitted. It can therefore be seen that a subscriber station which contains these Rufschaltelemente, set up for each type of operation can be.

From Fig. I it can be seen that the required capacitor ioi for achieving the improved call quality with a different capacity takes effect as soon as the hook switch is lifted. Contacts iog and 112 are then closed and form a bypass circuit for the digit pulse contact i i i. The resistor iio and capacitor ioi thus act in a known manner as spark quenching and at the same time as the inductive peak voltage of the line relay diminishing circle. This additional effect of the capacitor is inter alia. in the already mentioned USA.-patent explained.

The invention is not restricted to the exemplary embodiment, but rather can be modified without departing from the scope of the invention.

Claims (7)

PATENT CLAIMS: i. Selective call switching arrangement; In particular for subscriber stations in telephone systems, characterized in that a circuit tuned to the ringing frequency in parallel resonance with a capacitor (toi) and the coil of a paging device (2oo) is provided for the reception of a direct current or direct voltage superimposed ringing current (AC) is connected in series with a polarizing resistor (z. B. cold cathode tube TA, rectifier cd. Like.) In such a way that when the combined direct and alternating voltage is applied to the series circuit mentioned, the resonant circuit responds and activates the call device (2oo). 4th 2. Switching arrangement according to claim i, characterized in that the circuit is made in such a way that the coordinated circle (2oo, toi) is triggered once in each period becomes (3oi to 3o3). 3. Switching arrangement according to claim i and 2, characterized in that that a call device (2oo) with a coil, an armature, one by a spring prestressed clapper and two bells is provided and that the anchor and the corresponding pretensioned clapper respond to the vibrational current and the two Alternately strike the bells, the impulses arriving when the clapper acts against the spring tension. q .. Switching arrangement according to Claims i to 3, characterized characterized in that bias, resonance circuit and spring force are chosen so that both bells struck alternately with the same force and at the same time intervals will. 5. Switching arrangement according to claim i to q., Characterized in that two differently polarized receiving devices (TA, TC) are connected to a line, which can be optionally called by reversing the polarity of the DC voltage on the transmitting side. 6. Switching arrangement according to claim i to 5, characterized characterized in that one pair is different on each of the individual conductors of a double line polarized receiving devices are each connected to one pole, while the remaining poles are connected to earth. 7. Switching arrangement according to claim i to 6, characterized in that for the digit selection the resonance capacitor (ioi) through auxiliary changeover contacts (io9, 1i2) via a resistor (iio) as a spark quenching capacitor is switched in parallel to the digit pulse contact (i i i).